Composition of matter



Patented Nov.2l,

I UNITED STATE COMPOSITION OF MATTER Gwynne Allen, Long Beach, Calif., assignor to Petrolite Corporation, Ltd, St. Louis, Mo., a corporation of Delaware No Drawing. Application May 27. 1942,

. Serial No. 444.76?

11 Claims.

The object of this invention is to provide a new material or composition of matter which is particularly adapted for use as a demulsifier in the resolution of crude oil emulsions, and as a breakinducer in the doctor treatment of gasoline, but which may have uses in other arts that I have not yet investigated.

This invention is a continuation in part of my copending application, Serial No, 392,099, filed May 6, 1941. Referenceis also made to my application Serial No. 444,761, which subsequently matured as U. S. Patent No. 2,326,599, dated August 10, 1943; Serial No. 444,762, which subsequently matured as U. S. Patent No. 2,329,025,

dated September 7, 1943; co-pending application Serial No. 444,763; application Serial No. 444,764, which subsequently matured as U. S. Patent No. 2,326,602, dated August 10, 1943; co-pending application Serial No. 444,765; and application Serial No. 444,766, which subsequently matured as U. S. Patent No. 2,329,026, dated September 7, 1943.

The new composition of matter that constitutes my present invention consists of or comprises an aminated poly-carboxylic-acid-reacted polymeric sub-rubbery sulfur-converted ester of a polyhydric alcohol, and more particularly, an ester in which there are present at least 2 acyl radicals derived from unsaturated high molal monocarboxylic detergent-forming acids having mers begin to be formed, and a certain degree of elasticity becomes apparent. Molecular weight determinations show the presence of polymers, including diads and triads (dimers, trimers) etc. Destruction of the polymeric body, for example, by saponification with alkali, results in a reduction of the molecular weight, loss of the elastic propproduct of sulfur and an unsaturated high molal at least 8, and not more than 32, carbon atoms each.

It is known that when elemental sulfur is heated with a reactive detergent-forming carboxylic acid, for example, with oleic acid, the sulfur adds at the double bond in the oleic acid chain or radical. Where the oleic acid is employed in combination with a polyhydric alcohol such as glycerol, as for example, in triolein which'is the triglyceride of oleic acid, the reaction apparently does not stop with the formation of a simple addition product.

' Instead, as discussed in the literature, e. g., Knight and Stamberger, J. Chem. Soc. London, 1928, pp. 2791-8, triolein takes up additional sulfur atoms, possibly even tied in through the glyceryl radical. Also, it is probable that the-several fatty acid radicals present are also linked through sulfur atoms. Compare comparable reactions involving more reactive sulfur dichloride, and particulal'ly the formation of cyclic 'bisulfides. Such reactions indicate the rationale for thioglycerol formation, or more exactly, the formation of sulfurized esters of thioglycerol. See Chemistry of Synthetic Resins, Ellis, 1935, volume 2, 1176-77.

monocarboxylic detergent-forming acid having at least 8, and not more than 32, carbon atoms typifled by sulfurized oleic acid. I make no claim to the use of the free detergent-forming carboxylic acid and sulfur alone in preparing my reagent; but I employ the acid onlyin combination with a polyhydric alcohol compound containing two or more alcoholiform hydroxyl groups, inthe form of an ester of such acid and such polyhydric alcohol. a l

The compound containing the two or more alcoholiform hydroxyl groups may be a simple polyhydric alcohol, such for example as glycerol or ethylene glycol, or it may be a condensed polyhydric alcohol like polyglycerol, di-ethylene glycol, di-glycerol, or tri-glycerol. In addition to the above polyhydric alcohols, I may also use mannitan, sorbitan, pentaery-thritol, and dipentaerythritol. I may use other alcohols so long as they have two or more hydroxyl groups in the molecule, i. e. (polyhydric alcohols in which a carbon atom chain is interrupted at least once by oxygen, as exemplified by diethylene glycol previously mentioned). They are allcharacterized by containing two or more alcoholii'orm hydroxyl groups and by having the power to form esters with an unsaturated high molal monocarboxylic detergent-forming acid having at least 8 and not more than 32 carbon atoms.

Resinous andsimilar materials are sometimes classified as thermoplastic, thermo-settin and element-convertible." The expression element-convertible refers particularly to plastic coatings or drying oils in which hardening apparently is due to conversion into a new compound or composition by action of an element .used, often oxygen. Thus, drying'oils are often referred to as being oxygen-convertible. For practical purposes, the only other element finding wide application for this purpose is sulfur. Hencecertain products, and particularly certain oils, are referred to as sulfur-convertible," mean- At any rate, in the course of the reaction poly- 5 ing that they react with sulfur or sulfur dichloride to get polymeric materials, rubbery masses, factice, or the like.

The unsaturated high molal detergent-forming monocarboxylic acids employed by me in preparing my reagent are characterized by having a carbon atom chain, which I shall denote as R, containing at least 8 carbon atoms and not more than 32 carbon atoms, and which must contain at least one unsaturated bond, 'i. e., at least one ethylene linkage. Such acids are sometimes referred to as ethylenic.

The acyl radical may, of course, have present other non-functional groups, such as hydroxyl groups, acyl-ox'y groups, etc. It is only necessary that the presence of such groups does not detract from (a) the detergent-forming ability of the acids, and (b) their susceptibility to sulfur conversion. Suitability of substituted acids is indicated by very simple tests. For instance, saponiflc'ation with caustic potash, caustic soda, or the like, must yield a soap or soap-like material. Secondly, if the detergent-forming properties have not been eliminated by the presence of this substituent atom orradical, then it is only necessary to determine that susceptibility to sulfur conversion is still present. Such test is obviously the same procedure as is herein described for preparing my reagent, except that it is conducted on a small scale in the laboratory. If the sub- I stituted acid or ester, which has been previously determined to have detergent-forming properties, also shows sulfur conversion susceptibility, it is, of course, the obvious functional equivalent of the unsubstituted or unmodified acids or esters herein described, and may be used with equal or even greater effectiveness.

Such high molal acids maybe obtained from various sources, such as oils, fats, and waxes; or one may use petroleum acids, rosin acids, and the like. Petroleum acids include naturally-occurring naphthenic acids and also acids obtained by the oxidation of' hydrocarbons and waxes. Rosin acids include abietic acid, pyroabietic acids, and the like. Saturated acids, such as saturated fatty acids, saturated naphthenic acids, saturated oxidized petroleum acids, etc., can frequently be converted into an unsaturated acid by halogenization, followed by a reaction of the kind exempli- 'fied by the internal Wurtz reaction.

My preference is to use unsaturated fatty acids, due to their low cost and ready availability. One need not use a single fatty acid, but may use the mixture employed by saponification of a naturally-occurring oil or fat. For instance, special reference is made to the fatty acids, which occur naturally in olive oil, castor oil, peanut oil, cottonseed oil, fish oils, corn oil, soybean oil, linseed oil, sesame oil, lard oil, oleo oil, perillaoil, and many other naturally-occurring oils. Rapeseed oil, for example, contains appreciable proportions of tri-erucin, the tri-glyceride of erucic acid. I have found it useful to prepare my reagent.

As has been previously pointed out, the high molal acids are used-in the form of the polyhydric alcohol ester having at least 2 such high molal acid radicals present. erence to use the naturally-occurring fatty acids, it obviously follows that my preference is to use the naturally-occurring glycerides; However, if desired, one can obtain the high molal acids from any source and esterify such acids with various polyhydric alcohols, such as the glycols, in the conventional manner, to produce suitable esters, which may or may not have a free or unreacted Since it is my prefalcoholiform hydroxyl group present. The fatty 70 acid di-g'lycerldes typify these esters which contain a free or unreacted alcoholiform hydroxyl group (in the residue of the polyhydric alcohol, glycerol). The fatty acid tri-glycerldes do not possess this free alcoholiform hydroxyl. Both types of glyceride, for example, are suitable for my purpose, provided the fatty acid present satislies the above-expressed requirements. The manufacture of such esters is so well known that no description is required in the present instance.

One may select esters of the mixed type and such mixed esters may even contain acyl radicals which either are not high molal in character or are not unsaturated, i. e., ethylenic in nature. For instance, diolein may be reacted with one mol of acetic acid or one mol of stearic acid to give an ester which would be satisfactory for the present purpose. As an example of a modified tain an alcoholiform hydroxyl group. Ricinoleic acid would satisfy the requirement, in this case. If the ester be a di-glyceride, the free alcoholiform hydroxyl group present in the glyceryl radical is sufllcient to permit the di-glyceride to meet the above requirement.

I have found that, in addition to naturally-occurring fatty acids, addition and substitution products of fatty acids, which latter modified fatty acids bear a simple genetic relationship to the parent fatty acids from which they were derived-are also useful for making my reagent so long as they are in part unsaturated, i. e., possess some double bond, as shown by possession of an iodine number of appreciable magnitude, or in those cases where a detergent-forming carboxylic acid is first reacted with a poly-carboxylic acid in producing my reagent, only so long as they possess an alcoholiform hydroxyl group also.

Instead of employing natural poly esters of reactive detergent-forming carboxylic acids in preparing my reagent, I may use synthetic esters obtained by esterifying one or more reactive active detergent-forming carboxylic acid of the above kind will be termed a "poly ester in the present description. In all instances, it must contain two or more radicals or residues derived from reactive detergent-forming carboxylic acids,

' which may be the same or different acids; and it contains one or more radicals or residues derived from polyhydric alcohols. Diglycerides of unsaturated fatty acids are examples of poly esters, just as are the naturally-occurring tri-glycerides of unsaturated fatty acids.

The reaction of elemental sulfur with such a poly ester is at first one of simple addition of sulfur at the double bond in the chain R of an acid residue in such poly ester to form a sulfurized derivative which does not differ greatly ployed.

- K from the parent ester in properties. However, when the reaction is allowed to proceed at controlled tempratures, there is obtained a complex polymeric siilfurized product of high molecular weight, which is semielastic and highl viscous and which approaches the consistency of rubber, depending on the time and temperature of reaction and the proportions of reactants em- The nature of the chemical changes which take place is, to the best of my knowledge, not yet fully understood. I have referred above to a literature reference which suggests various mechanisms for the olymerization process. Without attempting to express exactly the composition of the reagents I employ, I desire to use those polymeric sulfurized bodies, obtained as above recited, which have a consistency short of rubber. Accordingly, I have termed them sub-rubbery" to denote a range of polymerization between the simple sulfur addition products, on one hand, and the non-- usable rubbers produced on super-polymerization, on the other. Such sub-rubbery products are capable of dissolving in solvents to produce fluid reagents which are' practicable to be used commercially.

After preparing the polymeric sub-rubbery sulfurized derivative of a poly ester of a reactive detergent-forming carboxylicacid as above recited, I may first aminate said derivative by means of an amino-bodyof the following kind, or I may first react said derivative with a poly-c'arboxylic acid of the following kind; but in all cases, prepaamine of the above-describedkind, and with a 'poly-carboxylic acid of the above-described kind,

to produce a. complex condensation product.

In preparing my preferred reagent, 1215 parts by weight of castor oil are heated to 180 C. Fifteen parts by weight of sulfur are added, and

the mixture is. stirred continuously for 45-60 minutes at 188190 C., or until a sample withdrawn from the reaction vessel and cooled is semi-elastic and transparent, indicating the complete absence of unreacted sulfur. To this sulfurizedbody there is then added 20 parts by weight of triethanolamine. The temperature is reduced somewhat by such addition, but is still sufficiently high to produce the desired reaction between the sulfurized castor oil body and the triethanolamine. To this product there is then added 19 parts by weight of phthalic anhydride and heating is continued, preferably at at least 135 C., until the phthalic anhydride is com- Dletely assimilated, as shown by the absence of ration of my reagent involves a step in which 7 amination is effected and a step in which a polycarboxylic acid is a reactant.

The class of alkanolamines for my purpose is characterized by the presence in the molecule of one or more alkanol or substituted alkanol groups, i. e., groups like -CHzOH, --C2H4OH, -C3HGOH, etc. They also contain one or more amino nitrogen atoms in the molecule. The commonest ex amples of the class are triethanolamine, diethanolamine, and monoethanolamine, but the class also includes, for example, ethylethanolamine, dipropanolamine, tripropanolamine, benzylethanolamine, cyclohexylpropanolamine, etc. In every case, the molecule of the alkanolamine contains one or more alkox or aralkoxy groups of the above kinds. One may also have amines of the same general type in which one or more simple alkanol groups is replaced by a related group containing an ether linkage. For example, the alkanol group in the ethanolamines is -C2H4OH. Amines containing, for example, the ether-linked group -C2H4OC2H4OH are equally suited to my purpose. Similarly, the aminobodies produced by an etherization reaction between a simple alkanolamine like an ethanolamine and a'polyhydric alcohol like glycerol are suitable for my purpose so long as. they retain their basic nature.

Poly-carboxylic acids include phthalic acid, oxalic acid, maleic acid, succinic acid, citraconic acid, citric acid, glutaric acid, etc., all of which contain two or more carboxyl groups, -COOH, in the molecule. I prefer to use dibasic acids having 8 carbon atoms or less. In preparing my reagent, the acid itself may be employed, or it may be preferable to employ the acid in the form of its anhydride. For example, phthalic anhydride is available at a reasonable price in a state of high technical purity. In some instances, the anhydride shows little or no tendency to produce undesirable secondary reactions that phthalic crystals when a small sample is placed on glass and allowed to cool.

As a second example of a reagent which I prefer to use, the following is given: 298 parts-of ricinoleic acid are mixed with 16 parts by weight of glycerol, and the mixture is agitated and 40 heated in the presence of dry hydrogen chloride gas at a temperature in excess of 100 C., for a period of time sufficient to produce an ester. (1 have found that reacting'fi hours at 150 C., is satisfactory to accomplish this.) (If this procedure is tedious or undesirable, the di-glyceride of ricinoleic acid may be prepared in any other desired manner. For example, di-glycerides are commonly prepared by treating two mols of the tri-glyceride with one mol of glycerol, in the presence of an alkaline catalyst.) The ester so produced is mixed with 15% of its weight of elemental sulfur, and the agitation and heating are continued until all the sulfur is assimilated, and a clear transparent product is obtained, as shown by a test on glass. The product has considerable viscosity and a semi-elastic nature. This product is then mixed with 53 parts by weight of diethanolamine at the same temperature, C., and

agitation is complete. Usually, heating may be discontinued on addition of the diethanolamine,

the reaction being completed before the temperature has dropped very much. There is then added As a third example, substitute di-olein for the di-ricinolein prepared and used in the second example, just recited. (In this instance, the oxalic acid reacts through the free alcoholiform .group of the glyceryl radical of the di-olein.)

Other esters of unsaturated fatty acids or other reactive detergent-forming carboxylic acids of the kind heretofore mentioned may be used instead of the castor oil and the ricinoleic acid. For example, I have used cottonseed oil instead of castor oil in making certain examples of my reagent and have found it to be useful therein. However, when cottonseed-oil is used, the reaction is not as smooth as when castor oil is emloyed. Also, it is usually found that longer heating is required to produce the desired reagent of optimum properties. It is, therefore, preferable to use castor oil rather than cottonseed oil, so far as I am now aware. Other alkanolamines may be used instead of the triethanolamine and diethanolamine, and other polycarboxylic acids The stages of polymerization and condensation and the elastic properties of the resulting products may be altered by varying the temperature [of the reaction, the time of the reaction, or the proportions of reactants employed, or any combination ofthese variables. I have found that the most effective reagents are those obtained by reacting 100 parts by weight of the ester with from 10 to 17 parts by weight of sulfur, controlling the temperature to avoid the evolution of hydrogen sulfide, so far as is practicable, and employing a time 'sufllcient to obtain highly polymerized products which are, however, still soluble in petroleum distillates; then aminating such sulfurized bodies with triethanolamine using approximately 10 to 20 parts by weight of the amine; and then reacting such aminated sulfurized bodies with approximately 10 to 20 parts by weight of phthalic anhydride.

While the foregoing description has shown products obtained by subjecting a sulfurized poly ester to the action of an alkanolamine and a polycarboxylic acid (and particularly in that order, the poly-carboxylic acid being reacted with the aminated sulfurized body in the examples cited), I have also found that in some instances the procedure may be modified in that the poly-carboxylic acid may be reacted with the polyester hydroxyl group of the glyceryl radical in a di-' glyceride, the poly ester will be reactive with the poly-carboxylic acid used.

In some instances, it may be found desirable to make the amination step the final one in the preparation of my reagent; but in general I do not find this desirable. I have found especially that if the sulfurization step be conducted after reacting the poly-carboxylic acid with the poly ester and before the amination step, the sulfurization of the acidic poly-carboxylic-acid-reacted poly ester does not proceed smoothly. Thereis considerable tendency to go too far in the sulfurization step under such conditions and to procluce an entirely rubbery, non-fluid product which is comparatively insoluble in solvents and is accordingly of little or no value. However, by proceeding cautiously, the operation can be conducted acceptably.

My invention, therefore, goes to (1) a reagent produced by reacting a poly-carboxylic acid with an aminated poly ester which has been sulfurized before amination; (2) a reagent produced by (4) a reagent produced by aminating a polyester, a then reacting with a poly-carboxylic acid, then sulfurizing; (5) a reagent produced by reacting a polyester withv a poly-carboxylic acid, then sulfurizing, then aminating; (6) and a reagent produced by reacting a poly ester with a polycarboxylic acid, then aminating, then sulfurizing. Reagents of types 5 and 6 are possible only when the poly ester has free alcoholiform hydroxyl groups, either in the reactive detergentforming carboxylic acid residue, as in the case of ricinoleic acid, or inthe glyceryl radical, as in di-glycerides. (Types 1 to 4, inclusive, may be produced from any poly ester containing the residue of an unsaturated detergent-forming acid.)

The products of all these types are broadly similar, although they are not necessarily of identical structural configuration.

In other words, I have found that it is possible to prepare reagents of broadly similar composition and of equally valuable properties by varying the order of conducting the steps of sulfurizing, aminating, and reacting the poly ester with a poly-carboxylic acid, so that in certain instances one procedure may offer advantages over the others, in that'it may be more adaptable to plant operations, or the product so obtained may be detectably superior to that produced by any other alternative procedure. My invention, therefore, contemplates conducting the steps of sulfurizing, aminating, and reacting a poly ester with a poly-carboxylic acid in any desired order (subject only to the limitation, explained above, that it may not always be possible to react the poly ester and the poly-carboxylic acid as the first step in the procedure). I

The final product will in some instances exhibit a free carboxyl group, COOH, depending on the proportions of poly-carboxylic acid added and the procedure employed in preparing the final product, all as recited above. Any acidity due to such free carboxyl group may be allowed to remain in the final product, or it may be neutralized by a suitable neutralizing agent, such as a metallic hydroxide or ammonia, or by a suitable alcohol in an esterification reaction.

The products so produced are sometimes somewhat basic in character. To the extent that basicity exists in the product, it may be used in its original form, or it may be neutralized wholly or in part by reaction with a suitable acid. I have found, for example, that the acetates and the lactates prepared by reacting such basic examples of my product with acetic or lactic acid frequently have notable merit. My invention is intended to include such salts, therefore.

The complex aminated poly-carboxylic-acidreacted polymeric sub-rubbery sulfurized compound obtained as recited above may bediluted with one or more solvents or diluents to improve its viscosity or other characteristics, as desired. Examples of suitable diluents are isopropanol, mineral spirits, benzol,.etc.

In employing my reagent as a demulsifying agent, it is usually employed in the proportion oilone part of reagent to from 2,000 to 20,000 parts of petroleum emulsion, either in concen- 2,scs,oss

trated form or after diluting as desired with a suitable vehicle or diluent or solvent. I desire to point outthat the superiority of my reagent or demulsifying agent is based on its ability to treat or break certain emulsions more advantageously and at a lower cost than is possible with other available demulsiflers or conventional mixtures thereof.

In practising the process of demulsifying petroleum oil by means of my new reagent it is brought into contact with or is caused to act upon the emulsion to be treated in any of the various ways or by any of the various apparatus now generally used to resolve or break -petroleum emulsions with a chemical reagent, the above procedure being used either alone or in combination with some other demulsiiying procedure, such as the electrical dehydration process.

While I have described in detail the preferred embodiment of my invention, it i understood that the materials employed, the proportions of ingredients, the arrangements of steps, and the details of procedure may be variously modified without departing from the spirit of the subjoined claims.

I claim:

1. A composition of matter, consisting of an alkanolamine reacted poly carboxylic-acid-reacted sub-rubbery polymeric sulfur-converted polyhydric alcohol ester; said ester prior to sulfur-conversion containing atleast 2 unsaturated high molal detergent-forming monocarboxylic acid radicals having at least. 8 carbon atoms and not more than 32 carbon atoms each; the reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190 C., and the reaction involving the polycarboxylic acid reactant beingconducted above 100 C. until examination reveals complete elimination of the uncombined reactant and ratios .of reactants being as follows: For each 100 'parts by weight of the high molal detergent-forming monocarboxy ester, there is employed 10 to 17 parts by weight of sulfur, 10 to 20 parts byweight of the alkanolamine and 10 to 20 parts by weight of the polycarboxylic reactant.

2. A composition of matter, consisting'of an alkanolamine reacted poly carboxylic-acid-reacted sub-rubbery polymeric sulfur-converted polyhydric alcohol ester; said ester prior to sulfur-conversion containing at least 2 unsaturated high molal detergent-forming monocarboxylic acid radicals having at least 8 carbon 7 atoms and not more than 32 carbon atoms each;

and said ester prior to sulfur-conversion being free from any unreacted hydroxyl radical a part or the alcoholic residue; the reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190 C. and the reaction involving polyhydric alcohol ester; said ester prior to' sulfur-conversion containing at least 2 unsatp 5 urated fatty acid radicals having at least 8 carbon atoms and not more than 32 carbon atoms each; and said ester prior to sulfur-conversion being free from any unreacted hydroxyl radical as part of the alcoholic residue; the reaction in-- volving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190 C. and the reaction involving the polycarboxylic acid reactant being conducted above C. until examination reveals complete eiiminationof the uncombined re- .polyhydric alcohol ester; said ester prior to sulfur-conversion containing at least 2 monoethylenic fatty acid radicals having at least 8 carbon atoms and not more than 32 carbon atoms each; and said ester prior to sulfur-conversion being free from any unreacted hydroxyl radical as part of the alcoholic'residue; the reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of C. to below C. and the reaction involving the polycarboxylic acid reactant being conducted above 100 C. until examination reveals complete elimination of the uncombined reactant, and ratios of reactants being as follows: For each 100 parts by weight of the high molal detergent-forming monocarboxy ester, there is employed 10 to 17 parts by' weight of sulfur, 10 to 20 parts by weight of the alkanolamine and 10 to 20 parts by weight of the polycarboxylic reactant.

5. A composition of matter, consisting of an alkanolamine reacted poly carboxylic-acid-reacted sub-rubbery polymeric sulfur-converted polyhydricalcohol ester; said ester prior to sulfur-conversion containing at least 2 radicals derived from monoethylenic fatty acids having 18 carbon atoms each; and said ester prior to ulfurconversion being free from any unreacted hydroxyl radical as part of the alcoholic residue; the reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190 C. and the reaction involving the polycarboxylic acid reactant being conducted above 100 C. until examination reveals complete elimination of the uncombined reactant, and ratios of reactants being as follows: For each 100 parts by weight of the highmolal detergent-forming monocarboxy ester, there is employed 10 to 17 parts by weight of sulfur, 10 to 20 parts by weight of the alkanolamine and 10 to 20 parts by weight of the polycarboxylic reactant.

6. A composition of matter, consisting of an alkanolamine reacted poly carboxylic-acid-reacted sub-rubbery polymeric sulfur-converted glycerol ester; said ester prior to sulfur-conver sion containing 3 monoethylenic fatty acid radicals having 18 carbon atoms each; and said ester prior to sulfur-conversion being free from any unreacted hydroxyl radical as part ofthe alcoholic residue; the reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190' C. and the reaction involving the polycarboxylic acid reactant being conducted above 100' C. until examination reveals complete elimination of the uncombined reactant, and ratios of reactants being as follows: For each 100 parts by weight of the high molal detergent-forming monocarboxy ester, there is'employed to 17 parts by weight of sulfur, in to 20 parts by weight of the alkanolamine and 10 to 20 parts by weight or the polycarboxylic reactant.

7. A' composition of matter, consisting. of an I alkanolamine reacted poly carboxylic-acid-reof the alkanolamine and 10 to 20 parts by weight of the polycarboxylic reactant.

8. A composition of matter, consisting of a triethanolamine reacted po -carboxylic-acid-reacted sub-rubbery polymeric sulfur-converted polyhydric alcohol ester; said ester prior to sulfur-conversion containing at least 2 unsaturated high molal detergent-forming monocarboxylic acid radicals having at least 8 carbon atoms and not more than 32 carbon atoms each; the reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190 C. and the reaction involving the polycarboxylic acid reactant being conducted above 100' C. until examination reveals complete elimination of the uncombined reactant, and ratios of reactants being as follows: For each 100 parts by weight of the high molal detergent-forming monocarboxy ester, there is employed 10 to 17 parts by weight of sulfur, 10 to 20 parts-by weight of the alkanolamine and 10 to 20 parts by weight of the polycarboxylie reactant.

9. A composition ofmatter, consisting of a triethanolami ne reacted poly carboxylic-acid-reacted sub-rubbery polymeric sulfur-converted tri-ricinolein; with reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190 C. and the reaction involving the polycarboxylic acid reactant being conducted above 100 C. until examination reveals complete elimination of the uncombined reactant, and ratios of reactants being as follows: For each 100 parts by weight of the high molal detergent-forming monocarboxy ester, there is employed 10 to 17 parts by weight or sulfur, 10 to 20 parts by weight of the alkanolamine and 10 to 20 parts by weight of the polycarboxylic reactant. v

10. A composition of matter, consisting of a trl-ethanolamine-reacted phthalic-acid-reacted sub-rubbery polymeric sulfur-converted polyhydric alcohol ester; said ester prior to sulfa conversion containing at least 2 unsaturated high molal detergent-forming monocarboxylic acid radicals having at least 8 carbon atoms and not more than 32 carbon atoms each; thereaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of 150 C. to below 190 C. and the reaction involving the polycarboxylic acid reactant being conducted above C. until examination reveals complete elimination of the uncombined reactant, and ratios of reactants being as follows: For each 100 parts by weight of the high molal detergent-forming monocarboxy ester, there is employed. 10 to 17 parts by weight of sulfur, 10 to 20 parts by weight oi the alkanolamine and 10' to 20 parts by weight of the polycarboxylic reactant.

11. A composition of matter, consisting of a tri-ethanolamine-reacted phthalic-acid-reacted sub-rubbery polymeric sulfur-converted triricinolein; the reaction involving the alkanolamine being conducted with almost immediate completeness at a temperature of C. to below C. and the reaction involving the polycarboxylic acid reactant being conducted'above 100 C. until examination reveals complete elimination of the uncombined reactant, and ratios of reactants being as follows: For each 100 parts by weight of the high molal detergent-forming monocarboxy ester, there is employed 10 to 17 parts by weight of sulfur, 10 to 20 parts by weight of the alkanolamine and 10 to 20 parts by weight of the polycarboxylic reactant.

GWYNNE ALLEN. 

